Axial-radial rolling bearing

ABSTRACT

Disclosed is an axial-radial rolling bearing having an inner ring, an outer ring disposed around the inner ring, and a plurality of rolling bodies in the form of rollers arranged into at least one row disposed between and separating the inner ring and the outer ring. The rolling bearing further includes at least one rolling bearing cage disposed around at least part of the rollers and configured to maintain a predetermined spacing of each of the rollers from each adjacent roller in the at least one row, wherein the rolling bearing cage comprises a plastic coated main body that is at least one of ring-shaped or segmented. The main body has openings for receiving the respective rolling elements.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application is a divisional of U.S. application Ser. No. 14/381,885, filed Aug. 28, 2014, which is a U.S. National Stage Application of International Application Serial No. PCT/EP2013/053948, filed Feb. 27, 2013, which claims priority to German Patent Application Serial No. DE 102012101651.8, filed Feb. 29, 2012, the entire contents of which are hereby incorporated by reference herein.

FIELD

This disclosure relates to a method for producing a rolling bearing cage for a rolling bearing which has at least one row of rolling bodies. The disclosure also relates to a rolling bearing, in particular an axial-radial rolling bearing, equipped with at least one such rolling bearing cage, the rolling bearing having an inner ring, an outer ring and the at least one row of rolling bodies in between.

BACKGROUND

The rolling bearing cage is provided for holding the rolling bodies in the form of rollers, that is to say in particular tapered rollers or cylindrical rollers, with a uniform spacing from one another. According to the prior art, corresponding cages may be in the form of an open or closed ring or formed from a multiplicity of segments.

It is known from practice for low cage forces in the case of small rolling bearings to be accommodated substantially without wear by means of plastics cages. In the case of large rolling bearings, the use of injection-molded plastics cages is firstly disadvantageous owing to the high costs for corresponding injection molds, in particular because large rolling bearings are normally also manufactured in relatively low unit quantities. Furthermore, in many cases, plastics cages for large rolling bearings do not exhibit adequate strength. Furthermore, it must be taken into consideration that, in particular in the case of tapered-roller bearings, the cages must also take the form of a section of the shell of a cone, and thus at least cannot readily be manufactured from a flat material.

Within the context of the present invention, it is the intention for the rolling bearing cage to be suitable in particular for large rolling bearings, such that the diameter of the cage is then at least one meter. At this size in particular, although cages can be manufactured inexpensively from simple plastics strips, they exhibit only very low strength in the circumferential direction and are thus not suitable for many applications. Here, it must also be taken into consideration that, specifically in the case of large rolling bearings, retroactive exchange of the bearing is, in part, associated with very high costs and very high outlay. High cage forces can be accommodated by cages composed of steel, wherein steel is sensitive to wear, in particular in the presence of poor lubrication. Additional measures such as nitriding or nitrocarburizing are expensive, as is the use of a high-grade metal with low wear characteristics, such as bronze.

DE 30 41 355 A1 discloses a cage for a conventional ball bearing with an inner raceway, an outer raceway and multiple balls arranged in between, wherein the cage is formed from two sheet-metal parts which each have a coating composed of plastic. The production of a cage of said type formed from two deformed and coated sheet-metal strips is cumbersome and is not suitable for large rolling bearings. Since the coating is initially applied to the punched parts in an electrostatic method or a flow bed method, transitions remain after the connection of the punched parts, at which transitions there can be an increased risk of damage. A thermoplastic, in particular polyamide, is provided as a coating for the purpose of reducing the areas of contact between the cage and the balls and protecting the inner and the outer raceway against wear and reducing the friction coefficient.

DE 197 51 003 A1 discloses a method and a device for coating workpieces with a powdery, granular, liquid or pasty coating medium, wherein the application of the coating medium is performed in a fluidized bed. Excess coating medium is removed before the final melting-on and adhesion to the workpiece. A cumbersome method procedure is thus required. The described method and the described device are provided in particular for endless workpieces which are then subsequently processed into their final shape.

WO 2011/003391 A1 discloses a cage for a rolling bearing, which cage can be manufactured in one piece from a solid material. The cage has deformation regions in order that the rolling bodies can initially be placed into the cage and then fixed after a deformation of the deformation regions. A coating of the cage is not described, and is also not possible because said coating would be destroyed as a result of the deformation of the deformation regions. Retroactive coating is also no longer possible owing to the rolling bodies that are then movably arranged within the cage.

DE 197 31 892 A1 generally describes the coating of an electrically conductive workpiece with a fluidized bed.

SUMMARY

The present disclosure provides a method for producing a rolling bearing cage, by means of which method an adequately strong but also more wear-resistant rolling bearing cage can be produced in a simple manner, in particular, even for large rolling bearings. It is furthermore sought to provide a rolling bearing, the rolling bearing cage of which is both inexpensive to produce and is also stable and durable.

BRIEF DESCRIPTION OF THE DRAWINGS

The present disclosure is described in detail below with reference to the attached drawing figures, wherein:

FIG. 1 is a side section view through an embodiment of an axial-radial rolling bearing of the present disclosure, showing two rows of tapered rollers, inner and outer rings, and rolling bearing cages;

FIG. 2 is a perspective detail view of an embodiment of a rolling bearing cage of FIG. 1;

FIG. 3 is an isometric detail section view of an embodiment of a rolling bearing cage of FIG. 2.

DETAILED DESCRIPTION

A method is disclosed herein for producing a rolling bearing cage for a rolling bearing. The rolling bearing has at least one row of rolling bodies. Within the context of the method, a ring or a ring segment composed of a metallic solid material, in particular of steel or aluminum, is or are provided. From the ring or the ring segments, by means of a deformation process and/or a cutting, material-removing process, a ring-shaped or segmented main body of the rolling bearing cage is formed which has openings for receiving in each case one rolling body.

The deformation process and/or the cutting, material-removing process are provided not only for forming the openings but also for defining the further form of the main body. Accordingly, for example, oblique contact surfaces may be formed that are suitable for contact with the inner ring or with the outer ring. Furthermore, during the formation of the main body, it is also possible for integrated chambers such as grease grooves to be formed on the rolling bearing cage, in which chambers lubricant can be accommodated in regions of the contact surfaces. Further means, such as bores for holding the main body during a subsequent coating process, may be generated.

As cutting, material-removing processes, use may be made in particular of milling, turning and drilling, which may also be used in combination. Cutting of a structure is furthermore possible by means of a thermal cutting process, for example by means of a laser.

Subsequently, in order to be thermally coated with a thermoplastic powder, the main body is heated and a temperature above a minimum coating temperature, wherein the main body is then immersed in a fluidized bed with the thermoplastic powder. While the main body is present in the fluidized bed, the plastic powder adheres to the main body and melts on, whereby a continuous coating is formed. Finally, the main body is removed from the fluidized bed after the coating process.

According to the invention, the main body is initially manufactured in its final shape before coating is then performed. After the removal of the main body from the fluidized bed, no further heating, deformation or the like is required, such that a highly uniform coating, which exhibits good adhesion at all locations, is generated over the entire ring.

Since the ring that forms the main body, or the ring segments that form the main body, are shaped from a solid material, it is also possible to realize very stable embodiments that can meet the demands on a large rolling bearing even under intense load.

Since, in the context of the invention, the main body for forming the rolling bearing cage is provided with a uniform coating, the openings of the main body for receiving rollers must have an oversize. Said oversize is dimensioned such that, even taking the coating into consideration, the rolling bodies can be accommodated without jamming but also with the least possible play.

The rolling bearing is preferably in the form of an axial-radial rolling bearing with at least two rows of rolling bodies, such that an inner ring and an outer ring are supported radially against one another and axially against one another regardless of the direction of the axial thrust forces. This means that all of the axial forces can be transmitted regardless of their direction (parallel or antiparallel).

The axial-radial rolling bearing may in particular be a two-row tapered-roller bearing with the oppositely inclined rows of tapered rollers, or else may be a three-row roller-type slewing joint. In the case of a roller-type slewing joint of said type, three rows of cylindrical rollers are provided as rolling bodies, of which a first and a third row provide axial support and a second row provides radial support. The second row is normally arranged between the first row and the third row.

Depending on the configuration of the axial-radial rolling bearing as a three-row roller-type slewing joint or two-row tapered-roller bearing, use is made of either cylindrical rollers or tapered rollers. The window-like openings correspondingly have a rectangular or trapezoidal outline for receiving the rollers. Even though the coating applied in the fluidized bed is highly uniform on planar sections of the main body, material accumulations can form in corners, in particular in the corners of the openings in the case of a rectangular or trapezoidal outline, which material accumulations can lead either to jamming with the rollers or, outside said corners, to considerable play. In a preferred refinement of the method according to the invention, in the case of a main body with window-like openings, it is therefore provided that, proceeding from a rectangular or trapezoidal outline, cutouts that extend beyond the respective outline are generated in the corners of the openings. In the corners there may for example be formed additional incisions or bores, wherein if a bore is generated, a circular segment shape is formed.

The main body formed from a ring or from ring segments may preferably be heated in an oven. Here, it must be taken into consideration that, owing to the provision of a solid material, it is necessary for an altogether relatively large amount of heat to be introduced.

Depending on the configuration of the main body as a ring or as ring segments, it is however also conceivable to implement inductive heating by means of an alternating electromagnetic field of an induction coil. In the case of a continuous ring, there is the advantage that even a large, coherent structure of said type can be heated. In the case of the main body in the form of a ring, the induction coil is preferably also of ring-shaped form and arranged concentrically with the ring. A concentric arrangement of the induction coil within or outside the ring yields a uniform gap, and thus particularly uniform heating.

Even if temperature losses during or after the heating should be kept as low as possible for energy efficiency reasons, it may be expedient within the context of the invention to provide an interval between the heating of the ring and the immersion in the fluidized bed, which interval serves to allow the temperature to homogenize.

Within the context of the invention, the selection of the temperature is of particular significance because, in the presence of an excessively low temperature, the powder that adheres to the main body in the fluidized bed can be melted on only to an inadequate extent. By contrast, in the presence of an excessively high temperature, there is the risk of the plastic becoming too runny, resulting in an uneven distribution of the coating owing to gravitational force. Finally, the temperature must be selected on the basis of the thermoplastic provided as a coating, wherein allowance must also be made for a degree of cooling during the coating process within the fluidized bed.

Within the context of the invention, the main body is formed by way of a deformation process and/or a cutting, material-removing process. Here, it must be taken into consideration that dirt can remain on the main body as a result of such a machining process. Furthermore, a surface structure specific to the machining process, with channels, grooves or non-uniformities, may be present, which under some circumstances impairs the subsequent coating with plastic. Against this background, provision is made, in a further method step after the deformation or machining process, for cleaning or some other surface treatment to be performed. What is particularly advantageous is the improvement of the surface by means of a particle jet, for example treatment by sandblasting or blasting with corundum. In the course of such a treatment step, dirt and superficial material defects can be eliminated. Furthermore, on the surface, a microstructure is generated which is particularly suitable for receiving a coating. Finally, strength and durability can be further improved by blasting the surface.

To improve the adhesion of the coating on the main body, the main body may be provided with an adhesion-promoting layer as primer before the coating process itself. Adhesion promoters based on organic solvents and synthetic polymers are particularly suitable, these preferably being applied before the heating process.

The present disclosure will be further explained below on the basis of the drawings, which illustrate merely an exemplary embodiment.

FIG. 1 shows a section through one side of an axial-radial large rolling bearing, wherein the axial-radial large rolling bearing has an inner ring 1, an outer ring 2 and two rows of rolling bodies 3 arranged in between. The two rows of rolling bodies 3 are arranged opposite one another in the axial direction, such that the inner ring is supported relative to the outer ring 2 both radially and also axially, regardless of the direction of axial thrust forces.

It can be seen from the sectional illustration of FIG. 1 that the rolling bodies 3 in the form of tapered rollers for each of the two rows are held spaced apart from one another by a rolling bearing cage 4. Furthermore, the rolling bearing cages 4 also have contact surfaces 5 at which the rolling bearing cages 4 are supported in each case against the inner ring 1.

In FIGS. 2 and 3, it is illustrated that the two rolling bearing cages 4 each have a stable main body 6 and an external coating 7 composed of a thermoplastic. To improve the adhesion of the coating 7 on the main body 6, a thin adhesion-promoting layer 8 is also provided as an intermediate layer.

The stable main body 6 is formed from a metallic solid material by way of a cutting, material-removing process, and may for example be milled from a solid ring. This yields the advantage that the main body 6 exhibits stability that is adequate even for a large rolling bearing. Furthermore, further contours can be generated as required during the production from the solid material. Accordingly, it can be seen in FIG. 2 that the openings 9 for receiving the tapered rollers as rolling bodies 3 have a substantially trapezoidal outline. In the corners of the openings 9, however, cutouts 10 are provided that extend beyond the outline. In the exemplary embodiment, additional bores are formed in the corners of the openings 9, such that said cutouts 10 have the form of circular segments.

The cutouts 10 are provided for preventing an accumulation of the coating 7 at the corners.

The coating 7 is preferably applied in a fluidized bed, with a highly uniform coating being formed. A material accumulation may however form in the corners of the openings 9 solely owing to the geometry, wherein owing to the additional cutouts 10, however, said material accumulation cannot lead to jamming with the rolling bodies 3.

While the main body 6 imparts a high degree of stability to the rolling bearing cage 4, the coating 7 generates a reduction in friction and provides effective protection against wear. Polyamide (PA) and polyether ketone, preferably polyether ether ketone (PEEK), with a layer thickness of between 0.4 mm and 1.3 mm are particularly suitable as coating 7.

The coating of the main body 6 is preferably performed in a fluidized bed, wherein the main body 6 is initially heated to a temperature suitable for the coating 7, at which temperature it is then subsequently the case that, in the fluidized bed, particles of a plastic powder adhere, melt on and form the continuous coating 7. 

What is claimed is:
 1. An axial-radial rolling bearing comprising: an inner ring; an outer ring disposed around said inner ring; a plurality of rolling bodies in the form of rollers arranged into at least one row disposed between and separating said inner ring and said outer ring; at least one rolling bearing cage disposed around at least part of said rollers and configured to maintain a predetermined spacing of each of said rollers from each adjacent roller in said at least one row, wherein said rolling bearing cage comprises a thermoplastic coated stable main body that is at least one of ring-shaped or segmented.
 2. The axial-radial rolling bearing of claim 1, wherein said rolling bearing is an axial-radial rolling bearing further comprising at least two rows of rolling bodies that are configured such that said inner ring and said outer ring are supported both radially against one another and axially against one another, regardless of a direction of axial thrust forces that may be imparted to the inner or outer rings of the axial-radial rolling bearing.
 3. The axial-radial rolling bearing of claim 2, wherein said at least two rows of rolling bodies are tapered rollers.
 4. The axial-radial rolling bearing of claim 2, further comprising three rows of rolling bodies, wherein said rolling bodies are cylindrical rollers, wherein a first row of cylindrical rollers and a third row of cylindrical rollers provide axial support for the axial-radial rolling bearing and a second row of cylindrical rollers provides radial support for the axial-radial rolling bearing.
 5. The axial-radial rolling bearing of claim 2, wherein said at least one rolling bearing cage comprises a plurality of rolling bearing cages, and wherein said at least one rolling bearing cage is configured in the shape of a ring having a diameter of at least one meter.
 6. The axial-radial rolling bearing of claim 1, wherein said stable main body is made of a metallic solid material.
 7. The axial-radial rolling bearing of claim 1, wherein the thermoplastic is a solidified thermoplastic material from a fluidized bed with thermoplastic powder.
 8. An axial-radial rolling bearing comprising: an inner ring; an outer ring disposed around said inner ring; a plurality of rolling bodies in the form of rollers arranged into at least one row disposed between and separating said inner ring and said outer ring; at least one rolling bearing cage disposed around at least part of said rollers and configured to maintain a predetermined spacing of each of said rollers from each adjacent roller in said at least one row, wherein said rolling bearing cage comprises a plastic main body that is at least one of ring-shaped or segmented.
 9. The axial-radial rolling bearing of claim 8, wherein said rolling bearing is an axial-radial rolling bearing further comprising at least two rows of rolling bodies that are configured such that said inner ring and said outer ring are supported both radially against one another and axially against one another, regardless of a direction of axial thrust forces that may be imparted to the inner or outer rings of the axial-radial rolling bearing.
 10. The axial-radial rolling bearing of claim 9, wherein said at least two rows of rolling bodies are tapered rollers.
 11. The axial-radial rolling bearing of claim 9, further comprising three rows of rolling bodies, wherein said rolling bodies are cylindrical rollers, wherein a first row of cylindrical rollers and a third row of cylindrical rollers provide axial support for the axial-radial rolling bearing and a second row of cylindrical rollers provides radial support for the axial-radial rolling bearing.
 12. The axial-radial rolling bearing of claim 9, wherein said at least one rolling bearing cage is configured in the shape of a ring having a diameter of at least one meter. 